The relationship of regulatory proteins and DNase I hypersensitive sites in the yeast GAL1-10 genes.

We have used yeast strains containing a disrupted positive (GAL4) and/or a disrupted negative (GAL80) regulatory gene to investigate the relationship of these regulatory proteins to the hypersensitive sites upstream of their target genes, GAL1-10. We find that neither of these regulatory proteins is required for the formation of the hypersensitive region. There is positive regulatory protein (dependent) binding to a portion of the hypersensitive region when GAL1 and 10 are expressed. However, similar binding can also occur under conditions in which the genes are not expressed. Thus, such binding is necessary but not sufficient for expression of GAL1 and 10 and control of GAL1-10 expression must also include processes which occur subsequent to GAL4/DNA binding. The negative regulatory protein GAL80 plays a significant role in these processes.     

A novel human hexameric DNA helicase: expression, purification and characterization

We have cloned, expressed and purified a hexameric human DNA helicase (hHcsA) from HeLa cells. Sequence analysis demonstrated that the hHcsA has strong sequence homology with DNA helicase genes from Saccharomyces cerevisiae and Caenorhabditis elegans, indicating that this gene appears to be well conserved from yeast to human. The hHcsA gene was cloned and expressed in Escherichia coli and purified to homogeneity. The expressed protein had a subunit molecular mass of 116 kDa and analysis of its native molecular mass by size exclusion chromatography suggested that hHcsA is a hexameric protein. The hHcsA protein had a strong DNA-dependent ATPase activity that was stimulated ≥5-fold by single-stranded DNA (ssDNA). Human hHcsA unwinds duplex DNA and analysis of the polarity of translocation demonstrated that the polarity of DNA unwinding was in a 5′→3′ direction. The helicase activity was stimulated by human and yeast replication protein A, but not significantly by E.coli ssDNA-binding protein. We have analyzed expression levels of the hHcsA gene in HeLa cells during various phases of the cell cycle using in situ hybridization analysis. Our results indicated that the expression of the hHcsA gene, as evidenced from the mRNA levels, is cell cycle-dependent. The maximal level of hHcsA expression was observed in late G₁/early S phase, suggesting a possible role for this protein during S phase and in DNA synthesis.     

Conditional gene expression by controlling translation with tetracycline-binding aptamers

We present a conditional gene expression system in Saccharomyces cerevisiae which exploits direct RNA–metabolite interactions as a mechanism of genetic control. We inserted preselected tetracycline (tc) binding aptamers into the 5′-UTR of a GFP encoding mRNA. While aptamer insertion generally reduces GFP expression, one group of aptamers displayed an additional, up to 6-fold, decrease in fluorescence upon tc addition. Regulation is observed for aptamers inserted cap-proximal or near the start codon, but is more pronounced from the latter position. Increasing the thermodynamic stability of the aptamer augments regulation but reduces expression of GFP. Decreasing the stability leads to the opposite effect. We defined nucleotides which influence the regulatory properties of the aptamer. Exchanging a nucleotide probably involved in tc binding only influences regulation, while mutations at another position alter expression in the absence of tc, without affecting regulation. Thus, we have developed and characterized a regulatory system which is easy to establish and controlled by a non-toxic, small ligand with good cell permeability.     

The application of Tet repressor in prokaryotic gene regulation and expression

Inducible gene expression based upon Tet repressor (tet regulation) is a broadly applied tool in molecular genetics. In its original environment, Tet repressor (TetR) negatively controls tetracycline (tc) resistance in bacteria. In the presence of tc, TetR is induced and detaches from its cognate DNA sequence tetO, so that a tc antiporter protein is expressed. In this article, we provide a comprehensive overview about tet regulation in bacteria and illustrate the parameters of different regulatory architectures. While some of these set‐ups rely on natural tet‐control regions like those found on transposon Tn10, highly efficient variations of this system have recently been adapted to different Gram‐negative and Gram‐positive bacteria. Novel tet‐controllable artificial or hybrid promoters were employed for target gene expression. They are controlled by regulators expressed at different levels either in a constitutive or in an autoregulated manner. The resulting tet systems have been used for various purposes. We discuss integrative elements vested with tc‐sensitive promoters, as well as tet regulation in Gram‐negative and Gram‐positive bacteria for analytical purposes and for protein overproduction. Also the use of TetR as an in vivo biosensor for tetracyclines or as a regulatory device in synthetic biology constructs is outlined. Technical specifications underlying different regulatory set‐ups are highlighted, and finally recent developments concerning variations of TetR are presented, which may expand the use of prokaryotic tet systems in the future.     

TMEM8 – a non-globin gene entrapped in the globin web

For more than 30 years it was believed that globin gene domains included only genes encoding globin chains. Here we show that in chickens, the domain of α-globin genes also harbor the non-globin gene TMEM8. It was relocated to the vicinity of the α-globin cluster due to inversion of an ∼170-kb genomic fragment. Although in humans TMEM8 is preferentially expressed in resting T-lymphocytes, in chickens it acquired an erythroid-specific expression profile and is upregulated upon terminal differentiation of erythroblasts. This correlates with the presence of erythroid-specific regulatory elements in the body of chicken TMEM8, which interact with regulatory elements of the α-globin genes. Surprisingly, TMEM8 is not simply recruited to the α-globin gene domain active chromatin hub. An alternative chromatin hub is assembled, which includes some of the regulatory elements essential for the activation of globin gene expression. These regulatory elements should thus shuttle between two different chromatin hubs.     

Natural variation of the Y chromosome suppresses sex ratio distortion and modulates testis-specific gene expression in Drosophila simulans

X-linked sex-ratio distorters that disrupt spermatogenesis can cause a deficiency in functional Y-bearing sperm and a female-biased sex ratio. Y-linked modifiers that restore a normal sex ratio might be abundant and favored when a X-linked distorter is present. Here we investigated natural variation of Y-linked suppressors of sex-ratio in the Winters systems and the ability of these chromosomes to modulate gene expression in Drosophila simulans. Seventy-eight Y chromosomes of worldwide origin were assayed for their resistance to the X-linked sex-ratio distorter gene Dox. Y chromosome diversity caused males to sire ∼63% to ∼98% female progeny. Genome-wide gene expression analysis revealed hundreds of genes differentially expressed between isogenic males with sensitive (high sex ratio) and resistant (low sex ratio) Y chromosomes from the same population. Although the expression of about 75% of all testis-specific genes remained unchanged across Y chromosomes, a subset of post-meiotic genes was upregulated by resistant Y chromosomes. Conversely, a set of accessory gland-specific genes and mitochondrial genes were downregulated in males with resistant Y chromosomes. The D. simulans Y chromosome also modulated gene expression in XXY females in which the Y-linked protein-coding genes are not transcribed. The data suggest that the Y chromosome might exert its regulatory functions through epigenetic mechanisms that do not require the expression of protein-coding genes. The gene network that modulates sex ratio distortion by the Y chromosome is poorly understood, other than that it might include interactions with mitochondria and enriched for genes expressed in post-meiotic stages of spermatogenesis.     

筛选抑制酿酒酵母生长的人类基因

【目的】基于人类基因文库,构建一个筛选抑制酿酒酵母生长的人类基因的方法,并运用此方法筛选含有生长抑制性人源蛋白质的酿酒酵母,用于分析人类基因的生理功能及其抑制剂的寻找。【方法】利用Gateway~(TM)重组技术将人类蛋白质编码基因构建到酿酒酵母表达质粒中。得到的质粒分别转化酿酒酵母细胞中,分析哪些基因的表达会抑制酿酒酵母的生长,并用绿色荧光蛋白标签对典型候选基因在酿酒酵母中的定位进行观察。【结果与结论】本研究建立了抑制酿酒酵母生长的人类基因的筛选方法,并运用此方法成功地从2991个人类蛋白质编码基因中筛选到29个显著抑制酿酒酵母生长的基因。其中一些是引起人类疾病的致病基因。例如,PDLIM4参与到骨质疏松症和前列腺癌的形成和发展,但其生理功能尚不清楚。我们的研究可能为揭示这些候选基因的功能和调节机制提供新的途径。